DE102008062829A1 - Hydraulic system control panel - Google Patents

Abstract

The invention relates to a hydraulic system control plate (20), comprising a first sealing layer (30) with first sealing sections (40), a second sealing layer (34) with second sealing sections (42), and at least one intermediate layer (30, 34) disposed between the sealing layers (30, 34). 32), wherein the sealing portions (40, 42) of at least one sealing layer (30, 34) in the sealing layer (30, 34) formed and by means of at least one intermediate layer (32) supported beads (44, 46).

Description

The The invention relates to a hydraulic system control plate comprising a first gasket layer with first sealing portions, a second gasket layer with second sealing portions, and at least one between the gasket layers arranged liner.

From the US 5,582,415 For example, a hydraulic system control plate having a multi-layer structure is known. This plate comprises an intermediate plate, which is provided on opposite sides with sealing layers. The gasket layers are formed by printed on the intermediate layer sealing portions.

From the DE 10 2007 019 946 A1 a gasket is known, which has an intermediate layer of a filter screen material. On opposite sides of the intermediate layer separate sealing layers are provided by the intermediate layer, on which sealing portions are arranged in the form of sealing beads.

Of these, The present invention is based on the object, to provide a hydraulic system control plate of the type mentioned, which is a good even at high hydraulic system pressures Has sealing effect.

These Task is at a hydraulic system control panel of the above mentioned type solved according to the invention, that the sealing portions of at least one sealing layer in the gasket layer molded and supported by means of at least one intermediate layer Have beads.

at the hydraulic system control plate according to the invention the sealing portions are formed as beads, which in at least one of the gasket layers are molded. These beads have at least a portion of material which is spaced from the intermediate plate is under bias and in the assembled state of a hydraulic system abuts a component to be sealed. In the area where the Beading is applied to the component to be sealed, this is of the intermediate layer spaced so that a free space is created in this area the bead can dodge. This is compared to the state the technique in which in profile massive sealing sections, for example in the form of Dichtwülsten, are provided, an improved Achieved sealing effect. As a result, the invention is suitable Hydraulic system control plate, in particular for hydraulic systems with high hydraulic system pressures.

at the beads can be closed in particular at the edge Beading (full beading) and / or margins that are open at the edges (semi-beading).

Further makes it possible to mold the beads into a gasket layer, that this gasket made separately from the liner can be, in particular by a forming process, and that subsequently the gasket layer can be joined with the intermediate layer. This allows a particularly simple and highly accurate Production of the hydraulic system control plate.

Especially it is preferred if the at least one intermediate layer has a higher Deformation resistance than at least one of the gasket layers. The deformation resistance is in particular the respective resistance of a position against bending, which respectively through the choice of material and the area moment of inertia a situation is determined. A higher area moment of inertia the liner results when this is a higher thickness or thickness than a respective gasket layer.

Further it is preferred if at least one of the gasket layers of a metallic material is made. This can be a special stable hydraulic system control plate can be provided.

It is particularly preferred if at least one of the gasket layers is made of a resilient material, in particular of a spring-hard steel. This allows a particularly simple integration of the beads in the gasket layers. The spring elasticity of the material makes it possible to prevent a plastic deformation of the material and a consequent reduction in the sealing effect of the hydraulic system control plate. Preferably, steels having a tensile strength of at least about 1000 N / mm ² , preferably of at least about 1200 N / mm ² , are preferably used for this purpose.

Advantageous it is when at least one of the gasket layers a gasket layer thickness from at least about 0.1 mm to at most about 0.5 mm. This allows a particularly good deformability the beads in contact with a component to be sealed.

Further it is preferred if the at least one intermediate layer of a metallic material is made, so that a stable hydraulic system control plate can be created.

In particular, the interlayer of the hydraulic system control plate is solid in cross-section, so that the sealing effect of the hydraulic system control plate achieved by elastic deformation of the beads is and not by a deformation of the liner. Preferably, the intermediate layer is a smooth, in particular flat, layer which has only passage openings.

According to one embodiment of the invention, the at least one intermediate layer has an interlayer thickness of at least about 0.5 mm to at most about 5 mm, preferably from 0.8 mm to 3 mm. Thereby, a liner with a high area moment of inertia can be provided, so that the resistance against bending of the hydraulic system control plate is minimum. In this way it can be prevented even at high hydraulic system pressures that the voltage applied to a component to be sealed portions of the beads are moved away from the component to be sealed. Preferably, the intermediate layer is not made of spring-hard steel, the tensile strength is preferably at most about 900 N / mm ² , in particular at most about 750 N / mm ² .

Especially it is preferred if the ratio between an intermediate layer thickness the at least one intermediate layer and a sealing layer thickness a gasket layer at least about 2 to 1, preferably at least about 8 to 1. This works the intermediate layer as a stable supporting position for supporting the beads, which in turn in comparatively thin gasket layers are integrated, so that the beads under pretension on a seal Component of the hydraulic system come to rest.

Further it is preferred if the ratio between an interlayer strength the at least one intermediate layer and a sealing layer thickness of a Sealing layer at most about 40 to 1, preferably at most about 20 to 1. These values allow a flat hydraulic system control plate with a stable intermediate layer and at least one elastically deformable To create a gasket layer.

at An embodiment of the invention provides that at least a part of the course of the first sealing portions and at least a part of the course of the second sealing portions relative to each other are offset. This can be turned away from each other Side of the hydraulic system control plate to be sealed components with sealed different geometries.

It but is additionally or alternatively also possible, that a part of the course of the first sealing portions and at least a part of the course of the second sealing portions relative to each other have no dislocation.

Further it is advantageous if at least a subset of the beads a Has circumferentially closed course. These beads extend annular around a region to be sealed, in particular a breakthrough of the hydraulic system control plate. Preferably also extends along the outer edge of the hydraulic system control plate a circumferential bead. It is possible that the Beading edges are closed (full bead) or open at the edge (Half crimp).

Further it is preferred if at least a subset of the beads a Has circumferentially open course, so that a sealed Area is not completely enclosed by a bead. Again, it is possible that the beads edge closed (full bead) or open at the edge (half bead)

A Another embodiment of the invention provides that at least a first bead and at least a second bead of a gasket layer arranged at an angle to each other and in a transition region connected to each other. This allows a crossing or adjoining arrangement of different beads of a Sealing layer, so that even very complex seal geometries can be produced.

Especially It is advantageous if at least one remote from the intermediate layer Surface of at least one sealing layer partially with a plastic coating is provided, in particular the beads on this surface at least along part of her Gradually provided with a plastic coating. hereby the sealing effect of a sealing portion can be further improved. The plastic coating is in particular a thermosetting plastic, which mechanically particularly stable is or an elastomeric material, which is particularly good to a sealed surface of a component to be sealed adapts.

Preferably are at least one of the gasket layers and at least one Interlayer locally connected to each other, preferably with each other welded and / or positively connected, especially riveted together. This way can be an easy one manufacturable and stable composite of gasket layers and the intermediate layer be created.

Additionally or alternatively, it is also possible that the gasket layers are attached at least in sections by crimping their edges on the intermediate layer, wherein the other gasket layer is recessed in those edge regions to avoid disturbing material application, in which the flare of the other gasket layer on the their repellent side of the Zwi situation.

Especially it is preferred if the hydraulic system control plate in the form of a Transmission control plate is formed.

Further it is preferred if the hydraulic system control plate a plurality of media ports (for example, ten media ports or more), wherein the media passage openings extend through the gasket layers and the liner and wherein the largest of the media passage openings a maximum extension of 35 mm, preferably 30 mm, in particular of 20 mm, has. This allows a flow of a Media through the media passage openings of the hydraulic system control plate passing through, by limiting the size the media passage openings is achieved that the hydraulic system control plate also in the area of the media passage openings sufficient is stable. Below the maximum extent of a media passage opening in particular, the diameter of a circular medium passage opening or generally the longest extent of extension a media passage opening understood.

To Another embodiment of the invention is at least a medium passage opening having a passage regulating means, preferably a filter or a check valve provided. This allows filtering of the media passage opening flowing medium or a control of the media stream.

Prefers it is further, if the Durchlassregulationseinrichtung in a Media passage opening of the intermediate layer is fixed, in particular at a boundary of the media passage opening or thereto is attached adjacent. This allows for a compact Structure of the hydraulic system control plate.

In Advantageously, the hydraulic system control plate is on maximum fluid pressure of at least about 30 bar, preferably of at least about 50 bar, in particular of at least designed around 80 bar, so they in particular as Transmission control plate can be used.

Further it is advantageous if the hydraulic system control plate so is designed such that a maximum sealing gap between the sealing portions a gasket layer and a sealed by means of these sealing portions Component of a hydraulic system at a predefinable maximum fluid pressure maximum about 15 μm, preferably at most about 10 microns, is. That way you can at a predeterminable maximum fluid pressure maximum permissible Leakage currents are defined.

Further The invention relates to a hydraulic system with a protruding described hydraulic system control plate. Such a hydraulic system is formed for example in the form of a hydraulic transmission.

Further Features and advantages of the invention are the subject of the following Description and the graphic representation of a preferred Embodiment.

In show the drawings:

1 a perspective view of an embodiment of a hydraulic system with a hydraulic system control plate;

2 a plan view of a section of a first sealing layer of the hydraulic system control plate according to 1 ;

3 a bottom view of a section of a second sealing layer of the hydraulic system control plate according to 1 ;

4 a side view of the hydraulic system control plate according to 1 along a in 2 with IV-IV designated section line in an enlarged view; and

5 a side view of the hydraulic system control plate according to 1 along in 2 with VV designated section line in greatly enlarged representation.

Same or functionally equivalent elements are in all figures denoted by the same reference numerals.

An embodiment in 1 illustrated hydraulic system 10 is formed for example in the form of a transmission control block. The hydraulic system 10 includes a first housing part 12 and a second housing part 14 , The first housing part 12 has a second housing part 14 facing first sealing surface 16 on; the second housing part 14 has a the first housing part 12 facing second sealing surface 18 on.

Between the sealing surfaces 16 and 18 is a hydraulic system control plate 20 arranged.

With the help of a connection device 22 can the housing parts 12 and 14 as well as between the housing parts 12 and 14 arranged hydraulic system control plate 20 be connected to each other. This creates the Verbindungseinrich tung 22 a force with which the housing parts 12 and 14 and the hydraulic system control plate 20 be clamped together.

The connection device 22 preferably comprises a plurality of connecting elements 24 , which are designed in particular as screws. For example, the first housing part 12 Fastener guides 26 , which are formed in particular in the form of apertures, on.

The second housing part 14 includes fastener receptacles 28 , which are formed in particular in the form of internal threads.

The hydraulic system control plate 20 is multi-layered and includes a first gasket layer 30 , which with the first sealing surface 16 of the first housing part 12 interacts. On the first sealing surface 16 opposite side of the first gasket layer 30 is a liner 32 arranged. The hydraulic system control plate 20 further comprises a second gasket layer 34 , which on the first gasket layer 30 opposite side of the liner 32 is arranged and with the second sealing surface 18 of the second housing part 14 interacts.

The gasket layers 30 and 34 and the liner 32 have aligned connector through-holes 36 for the passage of fasteners 24 on.

Furthermore, the gasket layers 30 and 34 and the liner 32 aligned media passage openings 38 for the passage of a medium through the hydraulic system control plate 20 through. The medium is preferably a fluid, in particular a transmission oil.

In the 2 is a section of the first gasket layer 30 shown; in 3 is a corresponding section of the second gasket layer 34 shown. The first gasket layer 30 has first sealing sections 40 on, the second gasket layer 34 second sealing sections 42 ,

The sealing sections 40 . 42 are in the gasket layers 30 . 34 molded and formed as beads. The beads are, for example, in the form of a semi-bead open at the edge 44 and in the form of a full bead closed at the edge 46 trained (cf. 4 ). half beads 44 are preferred on the outer edges of the hydraulic system control plate 20 used as well as at the passage openings 36 for fasteners 24 ; full beads 46 offer more design freedom with complex branched beads.

The half-seeds 44 and the full beads 46 each have a section of material 48 on which of the liner 32 is spaced. At the halfsick 44 is a material section 48 via a single adjoining support section 50 at the liner 32 supported. At the full bead 46 is a material section 48 with two opposite sides of the material section 48 arranged support sections 50 and 52 at the liner 32 supported. The support section 50 a half-bead 44 and the support sections 50 . 52 a full bead 46 each go into investment sections 54 about which at the liner 32 issue.

An illustration of a coating, in particular of a plastic material, has been omitted for the sake of clarity of the figures. The coating is at least on the surfaces of the gasket layers 30 . 34 present, that of the liner 32 face away. There it is preferably applied only partially. The coating is preferably at least in the region of the beads 44 . 46 ,

For the micro-seal between the gasket layers 30 . 34 and the liner 32 offer several variants. In addition to a partial coating in the area of the beads 44 . 46 on the to the liner 32 facing surface of the gasket layers 30 . 34 is also a full-surface coating of these surfaces possible. Alternatively, the surface of the intermediate layer opposite these surfaces can also be used 32 be coated.

Basically, partial coatings over full-surface coatings of the entire surface of a gasket layer are preferred because they can be applied so that no direct contact with the media passage openings 38 , in particular to through holes for hydraulic oil, arises.

A distance of 0.5 mm between the outer edge of the partial coating and the edge of a media passage opening is preferred 38 intended. This ensures that the coating does not peel off, so that the risk of clogging the media passage openings 38 is prevented. This can - but need not - dispense with the integration of a filter.

The coating of the beads 44 . 46 preferably extends beyond the actual bead area, the width of the coated area preferably has up to five times, preferably up to three and a half times the width of a bead. In addition, other areas of the surface of a gasket layer may be partially coated, for example, the environment of Durchgangsöff calculations 36 for fasteners 24 ,

Preferably, the intermediate layer 32 and the gasket layers 30 and 34 made of a metallic material. The liner 32 is for example made of a steel material or of an aluminum material. The gasket layers 30 and or 34 are made of spring steel, for example.

It is preferred if an interlayer thickness 56 the liner 32 a multiple of a gasket thickness 58 a gasket layer 30 and or 34 is.

A bead height of a bead 44 . 46 results from the distance 60 between one of the liners 32 facing side of a plant section 54 and an outside of a piece of material 48 , minus the gasket thickness 58 , For example, the bead height is greater than the gasket thickness by a factor of at least about 1.5 to at most about 3 58 ,

In addition to the beads 44 . 46 can be at least one of the gasket layers 30 . 34 support elements 62 have (see. 5 ). The support elements 62 are through in the gasket layers 30 . 34 embossed structures formed.

The support elements 62 have a support element height. The support element height results from the distance 64 the at the liner 32 adjacent side of a gasket layer 30 . 34 from an outside of a supporting element 62 minus the gasket thickness 58 , The support element height is preferably lower than the height of a bead 44 . 46 , In particular, the support element height is less than half the bead height. With the help of the support elements 62 becomes a compression travel of a full (or half) bead 46 ( 44 ) limited. Thus, for example, the smallest distance between the first sealing surface 16 of the first housing part 12 and one of the liner 32 facing side of a plant section 54 the first gasket layer 30 be limited to the support element height.

A support element 62 For example, has a wave-shaped profile and is preferably adjacent to a connector through-hole 36 arranged. A support element 62 For example, a connector passage opening 36 completely enclose. The profiling can follow with its outer contour or with their individual elements of the contour of the passage opening, the elements of the profiling can therefore be rectilinear or concentric with the passage opening. It is also possible for a support element 66 (see. 3 ) a connector passage opening 36 only partially ("crescent-shaped") encloses. As a result, the space required by a support element is reduced. In addition to the wave-shaped profiles, it is also possible, for example, to use cup-shaped or meandering, bead-like profiles in the surface.

The described construction of a hydraulic system control plate 20 allows a basically arbitrary course of the sealing sections 40 and 42 in the form of the beads 44 . 46 , In particular, has at least a first subset 68 the beads 44 . 46 a circumferentially closed course (see. 3 ). In this way, in particular, a media passage opening 38 enclosed in a ring and sealed.

A second subset 70 the beads 44 . 46 may have a circumferentially open course (see. 3 ), such that control of a media flow along at least one of the gasket layers 30 . 34 is possible.

The control of a media stream can be realized particularly well if a first bead 72 and a second bead 74 are arranged at an angle to each other and in a transition region 76 are interconnected (cf. 3 ). In the transition area 76 encounter beads arranged at an angle to each other 72 . 74 to each other and merge.

Further, it is possible that a part of the course of the first sealing portions 40 and a part of the course of the second sealing portions 42 relative to each other have no offset, as for example in the edge arranged semi-beads 44 the case may be (cf. 4 ). It is also possible that part of the course of the first sealing sections 40 and at least part of the course of the second sealing portions 42 are offset relative to each other, as in adjacent to a media passage opening 38 arranged full beads 46 the first gasket layer 30 and the second gasket layer 34 the case may be (cf. 4 ).

The layers 30 . 32 and 34 the hydraulic system control plate 20 can be produced independently of one another, in particular stamped and / or formed by reshaping. In the area of the boundary of a media passage opening 38 It is preferred if this is burr-free made or deburred, so that a detachment of a ridge is prevented in a fluid flowing through this opening.

QUOTES INCLUDE IN THE DESCRIPTION

This list The documents listed by the applicant have been automated generated and is solely for better information recorded by the reader. The list is not part of the German Patent or utility model application. The DPMA takes over no liability for any errors or omissions.

Cited patent literature

• US 5582415 [0002]
• DE 102007019946 A1 [0003]

Claims (23)

Hydraulic system control plate ( 20 ), comprising a first gasket layer ( 30 ) with first sealing sections ( 40 ), a second gasket layer ( 34 ) with second sealing sections ( 42 ), and at least one between the gasket layers ( 30 . 34 ) arranged intermediate layer ( 32 ), characterized in that the sealing sections ( 40 . 42 ) at least one gasket layer ( 30 . 34 ) in the gasket layer ( 30 . 34 ) and by means of at least one intermediate layer ( 32 ) supported beads ( 44 . 46 ) exhibit. Hydraulic system control plate ( 20 ) according to claim 1, characterized in that the at least one intermediate layer ( 32 ) has a higher deformation resistance than at least one of the gasket layers ( 30 . 34 ). Hydraulic system control plate ( 20 ) according to claim 1 or 2, characterized in that at least one of the gasket layers ( 30 . 34 ) is made of a metallic material. Hydraulic system control plate ( 20 ) according to one of the preceding claims, characterized in that at least one of the gasket layers ( 30 . 34 ) is made of a resilient material, in particular of a spring-hard steel. Hydraulic system control plate ( 20 ) according to one of the preceding claims, characterized in that at least one of the gasket layers ( 30 . 34 ) a gasket layer thickness ( 58 ) of at least about 0.1 mm to at most about 0.5 mm. Hydraulic system control plate ( 20 ) according to one of the preceding claims, characterized in that the at least one intermediate layer ( 32 ) is made of a metallic material. Hydraulic system control plate ( 20 ) according to one of the preceding claims, characterized in that the at least one intermediate layer ( 32 ) an interlayer thickness ( 56 ) of at least about 0.5 mm to at most about 5 mm, preferably from 0.8 mm to 3 mm. Hydraulic system control plate ( 20 ) according to one of the preceding claims, characterized in that the ratio between an interlayer thickness ( 56 ) of the at least one intermediate layer ( 32 ) and a gasket layer thickness ( 58 ) a gasket layer ( 30 . 34 ) is at least about 2 to 1, preferably at least about 8 to 1. Hydraulic system control plate ( 20 ) according to one of the preceding claims, characterized in that the ratio between an interlayer thickness ( 56 ) of the at least one intermediate layer ( 32 ) and a gasket layer thickness ( 58 ) a gasket layer ( 30 . 34 ) is at most about 40 to 1, preferably at most about 20 to 1. Hydraulic system control plate ( 20 ) according to one of the preceding claims, characterized in that at least part of the course of the first sealing sections ( 40 ) and at least part of the course of the second sealing sections ( 42 ) are offset relative to each other. Hydraulic system control plate ( 20 ) according to one of the preceding claims, characterized in that a part of the course of the first sealing sections ( 40 ) and at least part of the course of the second sealing sections ( 42 ) have no offset relative to each other. Hydraulic system control plate ( 20 ) according to one of the preceding claims, characterized in that at least a subset ( 68 ) of the beads ( 44 . 46 ) has a circumferentially closed course. Hydraulic system control plate ( 20 ) according to one of the preceding claims, characterized in that at least a subset ( 70 ) of the beads ( 44 . 46 ) has a circumferentially open course. Hydraulic system control plate ( 20 ) according to one of the preceding claims, characterized in that at least one first bead ( 72 ) and at least one second bead ( 74 ) a gasket layer ( 30 . 34 ) are arranged at an angle to each other and in a transition region ( 76 ) are interconnected. Hydraulic system control plate ( 20 ) according to one of the preceding claims, characterized in that at least one of the intermediate layer ( 32 ) facing away from at least one sealing layer ( 30 . 34 ) is partially provided with a plastic coating, in particular the beads ( 44 . 46 ) are provided on this surface at least along part of its course with a plastic coating. Hydraulic system control plate ( 20 ) according to one of the preceding claims, characterized in that at least one of the gasket layers ( 30 . 34 ) and the at least one intermediate layer ( 32 ) are locally connected to each other, preferably welded together and / or positively connected, in particular riveted together. Hydraulic system control plate ( 20 ) according to one of the preceding claims, characterized records that it is designed in the form of a transmission control plate. Hydraulic system control plate ( 20 ) according to one of the preceding claims, characterized by a plurality of media passage openings ( 36 ), which through the gasket layers ( 30 . 34 ) and the intermediate layer ( 32 ), with the largest of the media passages ( 36 ) has a maximum extension of 35 mm, preferably 30 mm. Hydraulic system control plate ( 20 ) according to claim 18, characterized in that at least one medium passage opening ( 36 ) is provided with a Durchlassregulationseinrichtung, preferably a filter or a check valve. Hydraulic system control plate ( 20 ) according to claim 19, characterized in that the passage regulation means in a medium passage opening ( 36 ) of the intermediate layer ( 32 is fixed. Hydraulic system control plate ( 20 ) according to one of the preceding claims, characterized in that it is designed for a maximum fluid pressure of at least about 30 bar, preferably of at least about 50 bar and more preferably of at least about 80 bar. Hydraulic system control plate ( 20 ) according to one of the preceding claims, characterized in that it is designed such that a maximum sealing gap between the sealing portions ( 40 . 42 ) a gasket layer ( 30 . 34 ) and one by means of these sealing sections ( 40 . 42 ) component to be sealed ( 12 . 14 ) of a hydraulic system ( 10 ) at a predeterminable maximum fluid pressure is at most about 15 microns, preferably at most about 10 microns. Hydraulic system ( 10 ) with a hydraulic system control plate ( 20 ) according to any one of the preceding claims.